KR20190059180A - Automatic winding device - Google Patents

Abstract

The purpose of the present invention is to provide an automatic wire winding device with improved operability and reliability. The device according to the present invention comprises: a lower case having a shaft; a bobbin which is provided to be rotatable around the shaft and on which a wire is wound; a spring having one end fixed to the shaft, and the other end fixed to the bobbin to provide a rotational force to the bobbin; a track cover coupled to the bobbin, and having a track formed thereon; a pin which is located between the bobbin and the track cover and which controls the rotation of the bobbin; and a pin guide spring for pressing the pin toward the track cover. The track cover includes an inner track which expands and contracts in radius of curvature along a circumferential direction, an outer track formed at an interval from the inner track, a connecting track for connecting the inner track and outer track, and a stop track for connecting the inner track and outer track and stopping the pin. The outer track includes a first spiral portion of which the radius of curvature gradually decreases in a first rotation direction and a second spiral portion of which the radius of curvature gradually decreases in a second rotation direction. The first spiral portion is connected to the stop track while the radius of curvature thereof decreases when the first spiral portion rotates in the first rotation direction. The second spiral portion is connected to the first spiral portion while the radius of curvature thereof decreases when the second spiral portion rotates in the second rotation direction.

Description

{AUTOMATIC WINDING DEVICE}

The present invention relates to an automatic rewinding apparatus. More particularly, the present invention relates to an automatic winding device for automatically winding an electric wire of a device having an electric wire such as an earphone or a mouse, ≪ / RTI >

In general, the earphone is a handset designed to be small enough to be mounted on the ear. As the popularity of smartphones has increased the time and opportunities for listening to music and videos on smartphones, it has become common to listen to music, watch movies, and listen to UCCs using mobile phones.

However, the earphone wires were often twisted or tangled together with other belongings in the bag. In order to prevent this, an earphone or a headset having an automatic winding function has been developed and used for the convenience of the user.

Korean Patent No. 10-1471903 discloses an automatic reeling apparatus used in an electronic apparatus. 1 is a view showing a conventional automatic winding device disclosed in Korean Patent No. 10-1471903. The conventional automatic winding apparatus includes a base plate 1, a fixed shaft 3 extending from either one side of the base plate 1 in a direction perpendicular to the base plate 1, A wire 9 that is fixed on the circumferential surface of the wheel 9 and has one end wound on the circumferential surface of the wheel 9 along the wheel 9 An elastic member 19 whose one end is fixed to the fixed shaft 3 and the other end is fixed to a certain portion of the wheel 9, A cap 27 which is rotatable together with the wheel 9 and has a ball track 25 on a surface facing the upper case 29, An upper case 29 provided with an elongated groove 35 and a cap 27 inserted between the ball groove 25 of the ball track 25 and the elongated groove 35 of the upper case 29 and integrally joined with the wheel 9 Date when rotated in one direction It comprises a ball (31) (Ball) rotating riding the track (25) found on the sandwiched 35 state.

The ball track 25 includes an outer track formed to be recessed in the circumferential direction of the cap 27 and an inner track recessed in the circumferential direction of the cap 27 while being formed inward of the outer track, Two or more connecting tracks connecting the outer track and the inner track while being inserted into the inner track, and a stop track recessed so that the ball 31 is seated in a section where the connecting track and the inner track are in contact with each other.

At this time, when the wire 15 is pulled, the wire 15 wound on the wheel 9 is released from the wheel 9 so that the wheel 9 and the cap 27 are rotated in one direction and the elastic member 19 The balls 31 are retracted while the balls 31 are inserted in the grooves 35 and travel on the outer tracks through the inner tracks and the connecting tracks. When the pulled wires 15 are placed, the elastic restoring force of the elastic members 19 The wheel 9 and the cap 27 are rotated in the reverse direction so that the ball 31 is moved in the longitudinal direction of the dent groove 35 and is seated on the stop track by the connecting track so that the wheel 9 and the cap 27 The wire 15 is held in a pulled state so that the wire 15 is not further rotated and when the wire 15 is pulled while the wire 15 is stopped, the ball 31 seated on the stop track comes out of the stop track Next, the wheel 9 and the cap 27 are rotated along the inner track, and the wheel 9 and the cap 27 are rotated by the elastic restoring force of the elastic member 19 As rotated in the effort put winding a wire 15 on the circumferential surface of the wheel (9).

The ball 31 is sandwiched between the flat grooves 35 of the upper case 29 and is engaged with the flat groove 35 when the cap 27 integrally coupled to the wheel 9 is rotated in one direction A predetermined step is formed between the inner track, the connecting track, the outer track, and the stop track of the ball track 25, and the ball 31 is moved to another track with a step Should be able to. Therefore, the distance between the step of the ball track 25 and the upper case 29 must be larger than the diameter of the ball 31, so that the ball 31 and the ball track 25 are not completely in contact with each other. The size of the ball 31 or the depth of the ball track 25 must be not less than a predetermined size since the ball 31 can not easily fall into the connecting track or the stop track when the ball 31 rotates along the inner track or the outer track, This is a disadvantageous structure.

FIG. 2 is a view showing a ball track of an automatic rewinding apparatus according to the related art. In the prior art, a physical step is formed on the track along which the ball 31 moves in the ball track, thereby preventing the ball 31 from moving in the reverse direction, thereby preventing erroneous operation. However, the conventional malfunction preventing structure by the physical step difference has a disadvantage in that a malfunction occurs frequently due to wear of the step portion during a continuous operation for a long time.

Further, when the ball 31 is inserted between the ball track 25 and the upper case 29 of the cap 27, excessive pressure is applied to the ball during assembly, or if the assembly is loose, there is a high possibility of malfunction. That is, it has a disadvantage in that it is sensitive to the change in Z axis height due to mechanical assembly.

An object of the present invention is to provide an automatic rewinding apparatus with improved operability and reliability.

The present invention relates to a lower case having a shaft, a bobbin which is rotatably installed on a shaft, a bobbin to which the wire is wound, a spring fixed to the shaft and fixed to the bobbin to provide a rotational force to the bobbin, A track cover having a track formed thereon, a pin disposed between the bobbin and the track cover for controlling the rotation of the bobbin, and a pin guide spring for pressing the pin toward the track cover, wherein the track cover has a radius of curvature An outer track, a connection track connecting the inner track and the outer track, a stop track connecting the inner track and the outer track and stopping the pin, and the outer track includes a first rotation And a second helical portion whose radius of curvature is gradually reduced in the second rotational direction, wherein the first helical portion has a radius of curvature gradually decreasing in the first rotational direction, Wherein the spiral portion is connected to the stop track while the radius of curvature is reduced when the spiral portion rotates in the first rotation direction and the second spiral portion is connected to the first spiral portion while the radius of curvature is reduced when the second spiral portion rotates in the second rotation direction. Provides a wrapping device.

According to another embodiment of the present invention, the connecting track is connected to a section where the curvature radius of the inner track is enlarged when rotating in the second direction.

According to another embodiment of the present invention, the stop track is connected to a section where the radius of curvature of the inner track is reduced when the stop track rotates in the first direction.

In another embodiment of the present invention, the inner track, the outer track, the connecting track, and the stop track have no step on the track.

Further, in another embodiment of the present invention, the pin guide spring may include a fixing portion fitted to the shaft, a rail portion extending from the fixing portion and guiding the pin, a support portion extending from the fixing portion to the opposite side of the rail portion, And an automatic rewinding device.

According to another embodiment of the present invention, there is provided an automatic rewinding apparatus, wherein the shaft has a longitudinal groove in an axial direction on an outer periphery thereof, and a fixing portion of the pin guide spring has a protrusion inserted into the longitudinal groove.

In addition, according to another embodiment of the present invention, the shaft has a lateral groove formed along the circumferential direction on its outer circumference, a fixing portion of the pin guide spring is inserted into the lateral groove, an E-ring inserted in the lateral groove, And an automatic winding device.

According to another embodiment of the present invention, the bobbin includes first and second fixing protrusions arranged side by side for fixing the spring, the spring includes a bending portion surrounding the outer circumference of the first fixing protrusion, And a U-shaped hook portion surrounding the U-shaped hook portion.

According to another embodiment of the present invention, an end of the hook portion is located outside the second fixing protrusion.

According to another aspect of the present invention, there is provided an automatic reeling apparatus characterized in that the first protrusion is formed with a gentle curve at an end thereof.

According to another aspect of the present invention, there is provided an automatic winding apparatus, further comprising a lower plate disposed between the bobbin and the spring and having a plurality of striking portions.

According to another aspect of the present invention, there is provided an automatic rewinding apparatus, further comprising an upper plate disposed on an upper portion of the spring, the upper plate having a space protruded upward.

The track formed on the lower surface of the cam cover is formed so that the radius of curvature of the connecting track increases from the inside toward the outside so that the traveling direction of the pin along the outer track can be determined, can do.

Further, the automatic rewinding apparatus provided by the present invention can cancel the Z-axis direction mechanism tolerance by controlling the winding by the pin pressed by the pin guide spring along the track, thereby realizing a more accurate and flexible operation .

Also, the automatic rewinding apparatus provided by the present invention improves the loosening and fatigue failure of the hooks outside the spring.

Further, the automatic line-winding device provided by the present invention can prevent cracking of the spring by forming a grease-free space for preventing leakage of grease that lubricates the spring.

Figure 1 shows a prior art automatic reeling device,
FIG. 2 is a view showing a ball track included in the automatic rewinding apparatus according to the related art,
3 is an exploded view of an automatic rewinding apparatus according to an embodiment of the present invention,
FIG. 4 is a bottom view of a cam cover included in the automatic rewinding apparatus according to an embodiment of the present invention, FIG.
5 is a perspective view illustrating a pin guide spring included in the automatic line-winding apparatus according to an embodiment of the present invention,
6 is a cross-sectional view illustrating an installation structure of a pin guide spring included in the automatic line-winding apparatus according to an embodiment of the present invention,
7 is a view showing an end portion of a spring included in the automatic rewinding apparatus according to the related art,
8 is a view showing a fixing structure of a spring and a bobbin included in the automatic rewinding apparatus according to an embodiment of the present invention,
9 and 10 are views showing a main spring lubrication structure of an automatic rewinding apparatus according to an embodiment of the present invention.

Hereinafter, the present invention will be described in more detail with reference to the drawings.

3 is an exploded view of an automatic rewinding apparatus according to an embodiment of the present invention. The automatic rewinding apparatus according to an embodiment of the present invention is assembled with the individual parts of the automatic rewinding apparatus on the lower case 100 having the shaft 120 positioned at the lowermost side of the automatic rewinding apparatus. The shaft 120 may be separately manufactured and coupled to the lower case 100, or may be integrally manufactured at the time of manufacture. In the shaft 120, some of the retractor parts are rotatably coupled with the remainder not rotatably.

The bobbin 300 is rotatably installed on the shaft 120, and the winding part 310, in which the wire 200 is wound, is located at the stop. The winding unit 310 is a space in which the wire 200 is wound and accommodated. In the upper and lower portions of the winding portion 310, a disk-shaped wall having a larger diameter than the winding portion 310 and capable of accommodating other components is provided. A spring receiving portion 320 for receiving a spring 400 to be described later is provided on the upper wall and a circuit receiving portion 330 for receiving the circuit portions 810, 820 and 830, which will be described later, . Three side walls are formed along the outer periphery of the spring receiving portion 320 and slits are formed in the side walls so that the side walls are divided into the long side wall 322 and the two projections 324 and 326.

The spring 400 is a spring spring, the inner end 410 is fixed to the shaft 120 and the outer end 420 is fixed to the protrusions 324 and 326 of the bobbin 300. The shaft 120 is formed with a slit 122 for inserting and fixing the inner end portion 410. When the wire 200 is released from the bobbin 300, the spring 400 shrinks and energy is stored. When the spring 400 is restored to its original state by the stored energy, the bobbin 300 is rotated to rotate the wire 200 ).

A lower plate 450 is disposed below the spring 400, and an upper plate 460 is disposed above the spring. A pin guide spring 500 is provided on the upper surface of the upper plate 460 and a pin 600 is installed on the pin guide spring 500. A pin guide spring 500 is mounted on the pin 600, To the track cover 700 side to be described later. The pin 600 is moved along the track formed on the track cover 700. [ Strictly speaking, the track cover 700 only rotates together with the bobbin 300, and the pin 600 is linearly moved in the radial direction by the pin guide spring 500. An E-ring 550 may be interposed between the pin guide spring 500 and the upper plate 460 in order to mount and fix the pin guide spring 500.

A terminal 810 connected to the wire 200 is fixed to the lower portion of the bobbin 300 and a PCB 830 and a wire side terminal 810 for power connection to the outside of the automatic winding apparatus are connected to the PCB 830 Thereby accommodating a brush 820 that provides a power connection between the terminal 810 and the PCB 830. The PCB 830 is fixed to the lower case 120 and the terminal 810 is installed on the bobbin 300 and rotates so that power is connected by the brush 820.

4 is a bottom view of the track cover. An inner track 710 having a distance from the axis along the circumferential direction is formed on the lower surface of the track cover 700, an outer track 720 formed with an interval from the inner track 710, an inner track 710 A connecting track 730 connecting the outer track 720 and the outer track 720 and a stop track 740 connecting the inner track 710 and the outer track 720 and allowing the pin 600 .

Referring to FIG. 2, the conventional ball track is used to prevent the erroneous rotation by using the height difference in the track. However, when the ball track is used for a long time, the step formed on the track is worn out and the malfunction is likely to occur.

However, in the track of the track cover 700 according to the embodiment of the present invention, the inner track 710 and the outer track 720 are not circular, but the radius of curvature of the track is reduced or enlarged at the time of rotation, The pin 600 follows the radial reduction path or the radial expansion path of the track. Actually, the track cover 700 rotates and the pin 600 only moves linearly, but for convenience, the pin 600 is rotated and moved. Referring to the drawing, the wire 200 is drawn when the pin 600 rotates counterclockwise along the track, and the wire 200 is wound when the pin 600 rotates clockwise.

The inner track 710 has a substantially oval shape in which the radius is enlarged and then reduced again. When the pin 600 rotates clockwise on the inner track 710, the radius of curvature of the inner track 710 rotates only along the inner track 710 while repeating enlargement, reduction, enlargement, and reduction. Since the inner track 710 and the stop track 740 are connected to each other at a position where the radius of curvature of the inner track 710 is reduced, the pin 600 moving along the inner track 710 has a reduced radius of curvature Direction. Therefore, the pin 600 does not fall into the stop track 740 located in the direction where the radius of curvature becomes larger, but continues to rotate only along the inner track 710. Therefore, even if a step or the like that restricts the movement in the direction of the stop track 740 is omitted between the inner track 710 and the stop track 740, the pin 600 is prevented from escaping from the inner track 710 to the stop track 740 Malfunction can be prevented.

When the pin 600 rotates counterclockwise on the inner track 710, it moves along the direction in which the radius of curvature of the inner track 710 becomes larger. When the pin 600 moves in the direction of increasing the radius of curvature of the inner track 710, Proceeds to the track 730, moves to the outer track 720, and then continues to rotate along the outer track 720.

The outer track 720 is generally circular, but has a first spiral portion 722 having a smaller curvature at the time of clockwise rotation on one side and a second spiral portion 724 having a smaller curvature at the time of counterclockwise rotation, And the first helical portion 720 is curved in a clockwise direction and is connected to the stop track 740. The second helical portion 724 is curved in a counterclockwise direction and is connected to the first helical portion 722. The pin 600 moved from the inner track 710 to the outer track 720 via the connecting track 730 is moved along the second spiral portion 724 and the first spiral portion 722 and the circular portion 726 And continues to rotate counterclockwise.

When the pin 600 rotates in the clockwise direction on the outer track 720, the second spiral portion 724, the circular section 726, and the first spiral portion 722 are sequentially rotated to pass through. When the pin 600 rotates in the counterclockwise direction and reaches the first spiral portion 722, the radius of the first spiral portion 722 moves in the direction of reducing the radius, (740) and stops on the stop track (740). At this time, as the pin 600 moves along the circular section 726, the pin 600 continues to maintain the circular path, and therefore, there is no reverse entry into the connecting track 730 in the direction in which the radius is reduced in the circular section 706 . Accordingly, a step for preventing entry from the external track 720 into the connecting track 730 is not required.

When the pin 600 is stopped on the stop track 740 and the wire 200 is slightly pulled and released, the pin 600 rotates counterclockwise and enters the inner track 710 and then continues clockwise The wire 200 is rewound on the bobbin 300 while rotating.

On the other hand, when the pin 600 is stopped on the stop track 720, when the wire 200 is continuously pulled, the stopper 720 rotates in the counterclockwise direction to enter the inner track 710 And continues to rotate counterclockwise to rotate the outer track 720 through the connecting track 730 in a counterclockwise direction to release the wire from the bobbin 300.

FIG. 5 illustrates a pin guide spring included in the automatic line-winding apparatus according to an embodiment of the present invention; FIG. 6 illustrates an installation structure of a pin guide spring included in the automatic line-winding apparatus according to an embodiment of the present invention; to be. The pin guide spring 500 includes a fixed portion 510 fitted to the outer periphery of the shaft 120, a rail portion extending to one side from the fixed portion 510 and having a rail slit linearly moving along the pin 600 520, and has a support portion extending to the opposite side of the rail portion 520 and bent upward to come into contact with the track cover 700. An E-ring 550 is provided under the pin guide spring 500 to form a gap between the upper plate 460 and the pins 600 moving along the rail 520. The protrusion 512 is formed in the fixing part 510 and inserted into the slit 122 of the shaft 120 described above to fix the pin guide spring 500 so as not to rotate relative to the shaft 120. On the other hand, the shaft 120 is provided with a circumferential lateral groove 124 on the outer circumference, and a part of the E-ring 550 is inserted into the lateral groove 124.

The rail portion 520 is bent to be positioned above the fixing portion 510 but does not contact the track cover 700. [ The rail portion 520 urges the pin 600 upward so that the top of the pin 600 may still be in contact with the track in the track cover 700. At this time, even if there is a tolerance in the contact portion between the pin 600 and the track due to the flexible upward and downward bending force of the rail portion 520, it is possible to exhibit excellent operability. Also, when the step on the track of the track cover 700 is moved, it can smoothly move along the path. Further, the pin guide spring 500 is made of SUS having good durability, and is free from abrasion even in continuous running for a long time. A support portion 530 is provided on the opposite side of the rail portion 520 to assist in bending and restoring the rail portion 520. When the rail portion 520 is bent downward, the support portion 530 abuts against and supports the track cover 700.

7 is a view showing an end portion of a spring included in the automatic rewinding apparatus according to the related art. The spring of the automatic line-winding device according to the related art is in a state in which a pulling force is generated when the spring is compressed so that the end portion of the hook, which is the engagement portion of the spring and the bobbin, is extended and comes out of the fixing portion of the bobbin, A phenomenon has occurred.

FIG. 8 is a view showing a fixing structure of a spring and a bobbin included in the automatic rewinding apparatus according to an embodiment of the present invention.

A side wall is formed along the outer periphery of the spring receiving portion 320 formed on the upper portion of the bobbin 300 and three slits are formed on the side wall so that the side wall is divided into a long wall 322 and two projections 324 and 326 . As described above, the inner end of the spring 400 is inserted and fixed in the slit 122 of the shaft 120, and the outer end 420 of the spring 400 is fixed to the side wall. The outer end 420 of the spring 400 is bent outwardly from the side wall through the slit so as to surround the outer surface of the first protrusion 324, And a U-shaped hook portion 426 surrounding the inner side surface and the outer side surface of the second projection 326. The bending portion 424 is provided at the front of the hook portion 426 so that the spring 400 is pressed against the outer end 420 of the spring 400 when the spring 400 is compressed. It is possible to prevent the hook portion 426 from being stretched at the time of compression. Further, since the end of the hook portion 426 is located outside the side wall, the curl and the end portion of the spring 400 are rubbed to prevent the curl of the spring 400 from being damaged.

In addition, by forming the end portion of the first projection 324 in a gentle curved line (with respect to the pulling direction), the accumulation of fatigue occurring in the spring 400 during compression and relaxation of the spring 400 is minimized, can do.

9 and 10 are views showing a main spring lubrication structure of an automatic line-winding apparatus according to an embodiment of the present invention. A lower plate 450 is disposed below the spring 400, and an upper plate 460 is disposed above the spring. The lower plate 450 is located in the spring receiving portion 320, that is, between the bobbin 300 and the spring 400. The lower plate 450 has a plurality of striking portions 452. The upper plate 460 has a plurality of protruded spaces 462 formed by stamping or the like. By making the grease in the striking area 452 and the protruded space 462, the curl of the spring 400 is rubbed against each other by lubricating the spring 400, thereby preventing heat and crack from occurring. Thereby improving the operational reliability of the automatic rewind device.

Claims (12)

A lower case having an axis;
A bobbin rotatably installed on the shaft, the bobbin being wound with the wire;
A spring having one end fixed to the shaft and the other end fixed to the bobbin to provide rotational force to the bobbin;
A track cover coupled to the bobbin and formed with a track;
A pin positioned between the bobbin and the track cover for controlling rotation of the bobbin; And
And a pin guide spring for pressing the pin toward the track cover side,
The track cover is an internal track that is enlarged and reduced in radius of curvature along the circumferential direction. It is formed with an interval to the inner track. It is an outer track, a connecting track connecting the inner track and the outer track, And a stop track,
The outer track includes a first spiral portion whose radius of curvature gradually decreases in the first rotation direction and a second spiral portion whose radius of curvature gradually decreases in the second rotation direction,
The first helical portion is connected to the stop track while the radius of curvature is reduced when the first helical portion rotates in the first rotation direction and the second helical portion is connected to the first helical portion while the radius of curvature is reduced when the second helical portion rotates in the second rotation direction Lt; / RTI > The method according to claim 1,
Wherein the connecting track is connected to a section where the radius of curvature of the inner track is enlarged when rotating in the second direction. The method according to claim 1,
Wherein the stop track is connected to a section where the radius of curvature of the inner track is reduced when rotated in the first direction. The method according to claim 1,
Wherein the inner track, the outer track, the connecting track, and the stop track have no step on the track. The method according to claim 1,
Wherein the pin guide spring has a fixing portion fitted to the shaft, a rail portion extending from the fixing portion and guiding the pin, and a support portion extending from the fixing portion to the opposite side of the rail portion and contacting the bottom surface of the track cover. Winding device. 6. The method of claim 5,
The shaft has a circumferential groove in its axial direction,
Wherein the fixing portion of the pin guide spring has a protrusion inserted into the longitudinal groove. The method according to claim 1,
The shaft has a lateral groove formed along the circumferential direction on the outer circumference,
The fixing portion of the pin guide spring is inserted into the lateral groove,
And an E-ring inserted in the lateral groove and disposed under the pin guide spring. The method according to claim 1,
The bobbin has first and second fixing protrusions arranged side by side for fixing the spring,
Wherein the spring has a bending portion surrounding the periphery of the first fixing protrusion and a U-shaped hook portion surrounding the inside and outside of the second fixing protrusion. 9. The method of claim 8,
And an end of the hook portion is located outside the second fixing protrusion. The method according to claim 1,
Wherein the first projection is formed with a gentle curve at an end thereof. The method according to claim 1,
Further comprising a lower plate disposed between the bobbin and the spring and having a plurality of striking portions. The method according to claim 1,
Further comprising an upper plate disposed at an upper portion of the spring and having a space protruding upwardly.

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